ITMI20001163A1 - INTERCONNECTION BETWEEN RING NETWORKS FOR TELECOMMUNICATIONS TYPE MS-SPRING AND SNCP. - Google Patents

Abstract

Described is an interconnection architecture between an MS-SP ring network and an SNCP ring network in a "Dual Node and Bridge and Switch" architecture through a primary interconnection node (M) and a secondary interconnection node (N) connected by an optical fibre span, said primary interconnection node (M) comprising means for carrying out a Drop and Continue (D and C) operation and a service selector (SSM) for each circuit. The architecture provides for closing said SNCP ring network (RING 2) through the service selector (SSM) of the primary node (M) of the MS-SP ring network. In this way the management of the selectors is simplified, less I/O interfaces as well as less optical fibre are used and the available band is better exploited. <IMAGE>

Description

DESCRIPTION

In today's telecommunications networks, it has become extremely important to have the ability to compensate for the failures that occur in the networks themselves without affecting the functionality of the service. Therefore ring architectures are used more and more often and furthermore telecommunication networks are generally equipped; of means of protection against possible failures of the elements that compose them.

In SDH MS-SPRING (Multiplexed-Shared Protection Ring) ring networks, for example, a distributed protection mechanism is implemented, which allows the automatic recovery of traffic in the presence of defects in the connection fibers. In other words, the MS-SP Ring networks perform automatic traffic recovery through a synchronized redirection of said traffic, which is implemented at each node of the ring. This operation is controlled by a protocol consisting of messages, which are continuously exchanged between adjacent nodes. This protocol and the operations it involves are defined by many international standards, issued by ANSI, ITU-T and ETSI, and are characterized by a certain set of rules and messages. See for example ITU-T Recommendation G. 841.

An SNCP ring network (see definition 3.31 given in ITU-T Recommendation G. 805) is a ring network with a type of protection that is modeled by an underlayer generated by expanding the connection point of the subnet (where, with " subnet "means that topological component used to carry out the routing of a specific characteristic information).

One of the most important network architectures is the interconnection of ring networks using a "Dual Node and Drop & Continue" architecture, ie an architecture in which two nodes of each ring are interconnected. The "Drop & Continue" function is a function implemented within a node where the traffic is extracted (drop) from the working channels on the ring and at the same time transmitted forward on the ring (continue).

The classical solution considers four network elements or nodes (two of one ring and two of the other ring) interconnected through STM-N interfaces; however, through the use of large ADMs (Add Drop Multiplexers) or DXCs (Digital Cross Connects) which essentially integrate two nodes and act as ring closers, it is possible to reduce the total number of interconnection nodes to two. In this case the interconnection is made in the matrix of the Network Element without using the STM-N interfaces.

The "Dual Node and Drop & Continue" architecture is known from the ITU-T G. 842 Recommendation, but only the case of four separate interconnection nodes is dealt with in this standard. Even if two nodes were to be integrated into one (thus avoiding the use of STM-N interfaces) this solution would be equally complicated from a management point of view since three selectors would still have to be used and managed for each circuit. Another drawback of this hypothetical solution in which two nodes are integrated into one is that it would be expensive in terms of fiber used and bandwidth utilization.

In light of the known solutions and their disadvantages, it is the main purpose of the present invention to indicate an interconnection architecture between a ring of the MS-SPRING type and a high-order SNCP ring of the "Dual Node and Drop & Continue" type, using only two nodes but avoiding the management complexity of known solutions.

A further object of the present invention is to provide an architecture of the aforesaid type which is less expensive in terms of optical fiber used and in terms of bandwidth.

These objects, in addition to others, are achieved through a method according to independent claim 1 and through a network element according to independent claim 2. Further advantageous characteristics of the invention are indicated in the respective dependent claims.

The idea behind the present invention consists in closing the SNCP ring directly in the Service Selector of the MS-SPRING ring.

The invention will certainly be clear in the light of the detailed description that follows, given purely by way of non-limiting example, to be read with reference to the attached drawings, in which:

- Fig. 1 shows an MS-SPRING ring interconnected with an SNCP ring in a "Dual Node and Drop & Continue" architecture made with four Network Elements in which the path is from node A to node H;

- Fig. 2 is similar to Fig. 1 but the path is in the opposite direction, ie from node H to node A;

- Fig. 3 shows an MS-SPRING ring interconnected with an SNCP ring in a "Dual Node and Drop & Continue" architecture made with only two Network Elements in which the path is from node A to node H;

- Fig. 4 is similar to Fig. 3 but the path is in the opposite direction, ie from node H to node A; And

- Fig. 5 shows an MS-SPRING ring interconnected with an SNCP ring in a "Dual Node and Drop & Continue" architecture according to the present invention.

In the different figures, the same reference numbers will be used to indicate the same functionally equivalent parts or components. In the various figures, a ring network type MS-SPRING (RING1) with four fibers and a ring network type SNCP (RING2) are always indicated, connected through nodes or network elements (C, D, E, F; M, N ). The node C of Figs. 1 and 2 (node M of Figs. 3-5) is considered the primary node of the MS-SPRING ring while node D of Figs. 1 and 2 (node N of Figs. 3-5) is considered the secondary node of the MS-SPRING ring. In RING1, the working (protected) fiber is indicated with gray "tubes" while the protective fiber is indicated with white "tubes". The various paths are represented with solid solid lines equipped with arrows to clearly indicate the direction (substantially in accordance with ITU-T G.842 Recommendation). Of course, the fact of representing the RING1 as a four-fiber ring is simply dictated by reasons of practicality of representation but the same concepts apply to two-fiber rings.

With reference to Fig. 1, a protected path from a source node A to a destination node H uses working fiber from A to C (primary node); in C the Drop & Continue (D&C) function is performed, ie the traffic is extracted towards node E of RING2 but is also passed on to secondary node D; from node E then passes to node G (which lets it pass freely) to destination node H; at the same time, the continued traffic passes from node D to node F until it also arrives at destination node H. In node H there is a Path Selector (PSH) that chooses the path coming from one side or the other (depending on the state of the path).

Fig. 2 illustrates the same architecture with path from H to A. The path goes from H (source node, RJNG2) to A (destination node, RING1). The signal from node H passes 1) to node G up to node E where it is i) extracted and sent to a Path Selector (PSE) and ii) continued towards the Service Selector (SSF) of node F; and 2) to node F where it is iii) extracted towards the SSF Service Selector and iv) continued towards the Path Selector PSE of node E. From the Path Selector PSE of node E, the path passes to a Service Selector SSC of the node C. Similarly, from the SSF Service Selector of node F the path passes to node D and to the SSC Service Selector of node C. The SSC Service Selector selects one of the two signals and sends it to destination node A.

This known solution has the disadvantages of using four nodes for the interconnection, band and tributary ports to make the interconnection between each pair of nodes.

The architecture of Figs. 3 and 4 is functionally similar to that of Figs. 1 and 2 but Network Elements C and E are integrated into a single network element M (in the form of an ADM or DXC). The same goes for nodes D and F, integrated in N. In this case, the advantage lies in the reduction of the equipment and interconnection interfaces but adds the disadvantage of having to manage three selectors (two of which (SSM, PSM) in the same matrix ), to have fiber not used in an optimal way between the primary and secondary nodes and to have waste of bandwidth.

Before moving on to describe the architecture according to the present invention with reference to Fig. 5, we will mention the concepts of primary node and Service Selector (SS) in a ring network of the MS-SPRING type. The primary node is the node that provides the Service Selection and Drop & Continue (D&C) functions for a tributary. Of course, different tributaries can have different designated primary nodes. A Service Selector (SS) is the function of a node used for interconnecting rings. It selects traffic from channels arriving from one side of the node or traffic entering the ring, depending on certain criteria.

As it will be immediately noticed, the architecture of the invention adopts a "Dual Node and Drop & Continue" type solution realized with only two connection nodes (M and N). The primary node of the MS-SPRING ring, node M, includes the SS'M Service Selector (or Bridge & Switch selector) and this selector is used to close the HO SNCP ring again.

Thus, a path entering the ring network MS-SPRING (RING1) from node A will arrive at the primary interconnection node M where it will be extracted towards the SNCP ring (RING2) inside the matrix, will cross the intermediate node G and will reach the Path selector (PS ^) of the destination node H. In the network element M the path is also continued (D&C) towards the secondary interconnection node N in order to reach the Path Selector (PSH) of the destination node H which will choose which of the two paths to exit.

The path from H to A will go through the SNCP ring (RING2) in both directions and will arrive at the Service Selector (SSM) of the primary node M both crossing the node G and the secondary node N and using the fiber section N-M of the MS-SPRING ring. The Service Selector (SSM) of the primary node M will in turn select one of the two signals and send it to the destination node A.

The most evident advantage of this solution is that the fiber section of the RING2 between the interconnection nodes is absent. The further advantage is that the number of STM-N ports used is reduced (one pair of I / O ports is saved for each Network Element).

A further and important advantage is given by the fact that the number of selectors that the Grid Operator and the Grid Element have to manage goes from three (known solution) to one. All this, of course, without penalizing in any way the reliability of breakages.

The functions of the primary and secondary nodes could be implemented with both hardware and software and for this reason the present invention comprises a computer program comprising coding means suitable for carrying out all the steps of the method when said program is run on a computer. It also comprises a computer readable medium having a program recorded therein, said computer readable medium comprising coding means adapted to perform all steps of the method when said program is run on a computer.

A new network architecture has been described to advantageously connect an MS-SPRING ring and an SNCP ring which satisfies all the intended purposes. Many changes, modifications, variations and various uses of the present invention, however, will become apparent to those skilled in the art after considering the present disclosure and accompanying drawings illustrating preferred embodiments thereof. All such changes, modifications, variations and various uses which do not depart from the spirit and scope of the invention are considered to be covered by the invention which is limited only by the following claims.

Claims (5)

CLAIMS 1. Method to interconnect an MS-SPRING ring network (RING 1) and an SNCP ring network (RING2) in a "Dual Node and Bridge & Switch" architecture through a primary interconnection node (M) and a secondary interconnection (N) connected by a stretch of optical fiber, called primary interconnection node (M) comprising means for carrying out a Drop & Continue (D&C) operation and a Service Selector (SSM) for each circuit, the method being characterized by the phase of: - close said SNCP ring network (RING2) through the Service Selector (SSM) of the primary node (M) of the ring network MS-SPRING. Method according to claim 1, wherein said step of closing said SNCP ring network (RING2) through the Service Selector (SSM) of the primary node (M) comprises the steps, performed in the primary interconnection node (M), from: - receive a signal entering the MS-SPRING ring network (RING2), extract it towards the said SNCP ring network (RING2) and continue it towards the secondary interconnection node (N) using the optical fiber section that connects the primary nodes and secondary (M, N); - choose, through said Service Selector (SSM), between - a signal coming from said SNCP ring network (RING2) and directly entering the primary node (M) and - a signal coming from said SNCP ring network (RING2), passed through the secondary node (N), and entering the primary node (M) along the optical fiber section that connects the primary and secondary nodes (M, N); and - sending said signal chosen by the Service Selector (SSM) towards the destination node (A) of the ring network MS-SPRING (RING1). 3. Network element (M) to interconnect an MS-SPRING ring network (RING1) and an SNCP ring network (RING2) in a "Dual Node and Bridge & Switch" architecture, said node comprising a Service Selector ( SSM) for each circuit, characterized by the fact that said Service Selector (SSM) chooses between - a signal coming from said SNCP ring network (RING2) and directly entering the primary node (M) and - a signal coming from said SNCP ring network (RING2), passed through the secondary node (N), and entering the primary node (M) along the optical fiber section that connects the primary and secondary nodes (M, N); and - sends said selected signal towards the destination node (A) of the ring network MS-SPRING (RING1). 4. A computer program comprising coding means suitable for carrying out all the steps of claims 1-2 when said program is run on a computer. 5. A computer readable medium having a program recorded therein, said computer readable means comprising coding means adapted to perform all the steps of claims 1-2 when said program is run on a computer.